Protein adsorption to (3-acrylamido propyl) trimethyl ammonium chloride-grafted Sepharose gel: Charge density reduction via copolymerizing with electroneutral monomer drastically increases uptake rate.

Abstract

Polymer-grafting to porous materials is an effective way to create protein ion-exchangers of high capacity and uptake rate because the 3D architecture of the polymeric ion exchange groups provides high binding space and facilitated transport of the bound protein. Herein, a new anion exchanger was fabricated by grafting (3-acrylamide propyl) trimethyl ammonium chloride (APTAC) onto Sepharose FF gel for protein adsorption and chromatography. The ion exchanger, denoted as FF-pAPTAC, presented high capacity but limited uptake rate in bovine serum albumin (BSA) adsorption due to the high charge density of the cationic polymer chains. To solve the problem, we proposed to copolymerize APTAC with an electroneutral monomer, acrylamide (AM), onto Sepharose FF to modulate the charge density of the grafted polymer chains. By decreasing the feeding molar ratio of APTAC to AM, the ionic capacity (IC) of the copolymerized resins, FF-p(AM-APTAC)n (n denotes IC in mmol/L), decreased, but the chain length could be remained almost unchanged due to the similar reactivity ratios of the two monomers. With decreasing IC, the static adsorption capacity (qm) of FF-p(AM-APTAC)n decreased gradually because of the decline of protein binding sites. The uptake rate, however, represented by the ratio of effective pore diffusivity to the free solution diffusivity (De/D0), exhibited a strong uptrend with decreasing IC, reaching ~2.5-fold of the maximum observed with FF-pAPTACn. It is considered that the decrease of charge density weakened protein binding strength to the chains and increased the chain flexibility, which consequently facilitated the transport of bound proteins on the chains. Moreover, at the same IC, each FF-p(AM-APTAC)n displayed similar adsorption capacity but high uptake rate as compared with its FF-pAPTACn counterpart mainly due to the longer chain length of the copolymer. Particularly, ~6.5-fold enhancement of De/D0 was observed at IC=50±2mmol/L. Both high adsorption capacity and uptake rate made FF-p(AM-APTAC)n exhibit superior dynamic binding performance. The findings proved that reducing chain charge density by copolymerizing an electroneutral monomer was promising for fabrication of high-performance protein ion exchangers.